Operating-system-level virtualization is a computer virtualization method in which the kernel of an operating system allows the existence of multiple isolated user-space instances, instead of just one. Such instances, which are sometimes called containers, virtualization engines (VEs) or jails (FreeBSD jail or chroot jail), may look like real computers from the point of view of programs running in them.
On Unix-like operating systems, this technology can be seen as an advanced implementation of the standard chroot mechanism. In addition to isolation mechanisms, the kernel often provides resource-management features to limit the impact of one container's activities on other containers.
Operating-system-level virtualization is commonly used in virtual hosting environments, where it is useful for securely allocating finite hardware resources amongst a large number of mutually-distrusting users. System administrators may also use it, to a lesser extent, for consolidating server hardware by moving services on separate hosts into containers on the one server.
Other typical scenarios include separating several applications to separate containers for improved security, hardware independence, and added resource management features. The improved security provided by the use of a chroot mechanism, however, is nowhere near ironclad. Operating-system-level virtualization implementations capable of live migration can also be used for dynamic load balancing of containers between nodes in a cluster.
Operating-system-level virtualization usually imposes little to no overhead, because programs in virtual partitions use the operating system's normal system call interface and do not need to be subjected to emulation or be run in an intermediate virtual machine, as is the case with whole-system virtualizers (such as VMware ESXi, QEMU or Hyper-V) and paravirtualizers (such as Xen or UML). This form of virtualization also does not require support in hardware to perform efficiently.
Operating-system-level virtualization is not as flexible as other virtualization approaches since it cannot host a guest operating system different from the host one, or a different guest kernel. For example, with Linux, different distributions are fine, but other operating systems such as Windows cannot be hosted.
Solaris partially overcomes the above described limitation with its branded zones feature, which provides the ability to run an environment within a container that emulates an older Solaris 8 or 9 version in a Solaris 10 host. Linux branded zones (referred to as "lx" branded zones) are also available on x86-based Solaris systems, providing a complete Linux userspace and support for the execution of Linux applications; additionally, Solaris provides utilities needed to install Red Hat Enterprise Linux 3.x or CentOS 3.x Linux distributions inside "lx" zones. However, in 2010 Linux branded zones were removed from Solaris; in 2014 they were reintroduced in Illumos, which is the open source Solaris fork, supporting 32-bit Linux kernels.
Some operating-system-level virtualization implementations provide file-level copy-on-write (CoW) mechanisms. (Most commonly, a standard file system is shared between partitions, and those partitions that change the files automatically create their own copies.) This is easier to back up, more space-efficient and simpler to cache than the block-level copy-on-write schemes common on whole-system virtualizers. Whole-system virtualizers, however, can work with non-native file systems and create and roll back snapshots of the entire system state.
|Mechanism||Operating system||License||Available since or between||Features|
|File system isolation||Copy on Write||Disk quotas||I/O rate limiting||Memory limits||CPU quotas||Network isolation||Nested virtualization||Partition checkpointing and live migration||Root privilege isolation|
|chroot||most UNIX-like operating systems||varies by operating system||1982||Partial[a]||No||No||No||No||No||No||Yes||No||No|
|Docker||Linux, FreeBSD, Windows x64 (Pro, Enterprise and Education)||Apache License 2.0||2013||Yes||Yes||Not directly||Yes (since 1.10)||Yes||Yes||Yes||Yes||No||Yes (since 1.10)|
|Linux, Windows Server 2016||GNU GPLv2||2001||Yes||Yes||Yes||Yes[b]||Yes||Yes||Partial[c]||?||No||Partial[d]|
|lmctfy||Linux||Apache License 2.0||2013||Yes||Yes||Yes||Yes[b]||Yes||Yes||Partial[c]||?||No||Partial[d]|
|OpenVZ||Linux||GNU GPLv2||2005||Yes||Yes (ZFS)||Yes||Yes[g]||Yes||Yes||Yes[h]||Partial[i]||Yes||Yes[j]|
|Solaris Containers (Zones)||illumos (OpenSolaris),
|FreeBSD jail||FreeBSD, DragonFly BSD||BSD License||2000||Yes||Yes (ZFS)||Yes[s]||Yes||Yes||Yes||Yes||Yes||Partial||Yes|
|sysjail||OpenBSD, NetBSD||BSD License||2006–2009||Yes||No||No||No||No||No||Yes||No||No||?|
|iCore Virtual Accounts||Windows XP||Proprietary: Freeware||2008||Yes||No||Yes||No||No||No||No||?||No||?|
- Application virtualization
- Portable application creators
- Platform virtualization
- Separation kernel
- Storage hypervisor
- Virtual private server (VPS)
- Root user can easily escape from chroot. Chroot was never supposed to be used as a security mechanism.
- Utilizing the CFQ scheduler, there is a separate queue per guest.
- Networking is based on isolation, not virtualization.
- A total of 14 user capabilities are considered safe within a container. The rest may cannot be granted to processes within that container without allowing that process to potentially interfere with things outside that container.
- Disk quotas per container are possible when using separate partitions for each container with the help of LVM, or when the underlying host filesystem is btrfs, in which case btrfs subvolumes are automatically used.
- I/O rate limiting is supported when using Btrfs.
- Available since Linux kernel 2.6.18-028stable021. Implementation is based on CFQ disk I/O scheduler, but it is a two-level schema, so I/O priority is not per-process, but rather per-container.
- Each container can have its own IP addresses, firewall rules, routing tables and so on. Three different networking schemes are possible: route-based, bridge-based, and assigning a real network device (NIC) to a container.
- Docker containers can run inside OpenVZ containers.
- Each container may have root access without possibly affecting other containers.
- Available since version 4.0, January 2008.
- Docker containers can run inside Virtuozzo containers.
- Yes with illumos
- See OpenSolaris Network Virtualization and Resource Control for more details.
- Only when top level is a KVM zone (illumos) or a kz zone (Oracle).
- Starting in Solaris 11.3 Beta, Solaris Kernel Zones may use live migration.
- Cold migration (shutdown-move-restart) is implemented.
- Non-global zones are restricted so they may not affect other zones via a capability-limiting approach. The global zone may administer the non-global zones.
- Check the "allow.quotas" option and the "Jails and File Systems" section on the FreeBSD jail man page for details.
- Available since TL 02.
- Hogg, Scott (2014-05-26). "Software Containers: Used More Frequently than Most Realize". Network World. Network World, Inc. Retrieved 2015-07-09.
There are many other OS-level virtualization systems such as: Linux OpenVZ, Linux-VServer, FreeBSD Jails, AIX Workload Partitions (WPARs), HP-UX Containers (SRP), Solaris Containers, among others.
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- Linux-VServer Paper, Secure Capabilities
- Graber, Stéphane (1 January 2014). "LXC 1.0: Security features [6/10]". Retrieved 12 February 2014.
LXC now has support for user namespaces. [...] LXC is no longer running as root so even if an attacker manages to escape the container, he’d find himself having the privileges of a regular user on the host
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- "Docker inside CT".
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- Pijewski, Bill. "Our ZFS I/O Throttle".
- Network Virtualization and Resource Control (Crossbow) FAQ
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Jails were first introduced in FreeBSD 4.0 in 2000
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- An introduction to Virtualization
- A short intro to three different virtualization techniques
- Virtualization and Containerization of Application Infrastructure: A Comparison, June 22, 2015, by Mathijs Jeroen Scheepers
- Containers and persistent data, LWN.net, May 28, 2015, by Josh Berkus